v2/monoid/apply.go

// Copyright (c) 2023 - 2025 IBM Corp.
// All rights reserved.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.

package monoid

import (
	S "github.com/IBM/fp-go/v2/semigroup"
)

// ApplicativeMonoid lifts a monoid into an applicative functor context.
//
// This function creates a monoid for applicative functor values (HKTA) given a monoid
// for the base type (A). It uses the applicative functor's operations (of, map, ap)
// to lift the monoid operations into the applicative context.
//
// This is useful for combining values that are wrapped in applicative contexts
// (like Option, Either, IO, etc.) using the underlying monoid's combination logic.
//
// Type Parameters:
//   - A: The base type with a monoid
//   - HKTA: The higher-kinded type representing the applicative functor applied to A
//   - HKTFA: The higher-kinded type representing the applicative functor applied to func(A) A
//
// Parameters:
//   - fof: The "pure" or "of" operation that lifts a value into the applicative context
//   - fmap: The map operation for the applicative functor
//   - fap: The apply operation for the applicative functor
//   - m: The monoid for the base type A
//
// Returns:
//   - A Monoid[HKTA] that combines applicative values using the base monoid
//
// Example (conceptual with Option-like type):
//
//	type Option[A any] struct { value *A }
//
//	intAddMonoid := MakeMonoid(
//	    func(a, b int) int { return a + b },
//	    0,
//	)
//
//	optMonoid := ApplicativeMonoid(
//	    some,  // func(int) Option[int]
//	    fmap,  // func(Option[int], func(int) func(int) int) Option[func(int) int]
//	    fap,   // func(Option[func(int) int], Option[int]) Option[int]
//	    intAddMonoid,
//	)
//
//	// Combine Option values using addition
//	result := optMonoid.Concat(Some(5), Some(3))  // Some(8)
//	empty := optMonoid.Empty()                     // Some(0)
func ApplicativeMonoid[A, HKTA, HKTFA any](
	fof func(A) HKTA,
	fmap func(HKTA, func(A) func(A) A) HKTFA,
	fap func(HKTFA, HKTA) HKTA,

	m Monoid[A],
) Monoid[HKTA] {

	return MakeMonoid(
		S.ApplySemigroup(fmap, fap, m).Concat,
		fof(m.Empty()),
	)
}
Implement v2 using type aliases (#141) * fix: initial checkin of v2 Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: slowly migrate IO Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: migrate MonadTraverseArray and TraverseArray Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: migrate traversal Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: complete migration of IO Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: migrate ioeither Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: refactorY Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: next step in migration Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: adjust IO generation code Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: get rid of more IO methods Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: get rid of more IO * fix: convert iooption Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: convert reader Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: convert a bit of reader Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: new build script Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: cleanup Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: reformat Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: simplify Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: some cleanup Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: adjust Pair to Haskell semantic Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: documentation and testcases Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: some performance optimizations Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: remove coverage Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> * fix: better doc Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> --------- Signed-off-by: Dr. Carsten Leue <carsten.leue@de.ibm.com> 2025-11-06 09:27:00 +01:00			`// Copyright (c) 2023 - 2025 IBM Corp.`
			`// All rights reserved.`
			`//`
			`// Licensed under the Apache License, Version 2.0 (the "License");`
			`// you may not use this file except in compliance with the License.`
			`// You may obtain a copy of the License at`
			`//`
			`// http://www.apache.org/licenses/LICENSE-2.0`
			`//`
			`// Unless required by applicable law or agreed to in writing, software`
			`// distributed under the License is distributed on an "AS IS" BASIS,`
			`// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.`
			`// See the License for the specific language governing permissions and`
			`// limitations under the License.`

			`package monoid`

			`import (`
			`S "github.com/IBM/fp-go/v2/semigroup"`
			`)`

			`// ApplicativeMonoid lifts a monoid into an applicative functor context.`
			`//`
			`// This function creates a monoid for applicative functor values (HKTA) given a monoid`
			`// for the base type (A). It uses the applicative functor's operations (of, map, ap)`
			`// to lift the monoid operations into the applicative context.`
			`//`
			`// This is useful for combining values that are wrapped in applicative contexts`
			`// (like Option, Either, IO, etc.) using the underlying monoid's combination logic.`
			`//`
			`// Type Parameters:`
			`// - A: The base type with a monoid`
			`// - HKTA: The higher-kinded type representing the applicative functor applied to A`
			`// - HKTFA: The higher-kinded type representing the applicative functor applied to func(A) A`
			`//`
			`// Parameters:`
			`// - fof: The "pure" or "of" operation that lifts a value into the applicative context`
			`// - fmap: The map operation for the applicative functor`
			`// - fap: The apply operation for the applicative functor`
			`// - m: The monoid for the base type A`
			`//`
			`// Returns:`
			`// - A Monoid[HKTA] that combines applicative values using the base monoid`
			`//`
			`// Example (conceptual with Option-like type):`
			`//`
			`// type Option[A any] struct { value *A }`
			`//`
			`// intAddMonoid := MakeMonoid(`
			`// func(a, b int) int { return a + b },`
			`// 0,`
			`// )`
			`//`
			`// optMonoid := ApplicativeMonoid(`
			`// some, // func(int) Option[int]`
			`// fmap, // func(Option[int], func(int) func(int) int) Option[func(int) int]`
			`// fap, // func(Option[func(int) int], Option[int]) Option[int]`
			`// intAddMonoid,`
			`// )`
			`//`
			`// // Combine Option values using addition`
			`// result := optMonoid.Concat(Some(5), Some(3)) // Some(8)`
			`// empty := optMonoid.Empty() // Some(0)`
			`func ApplicativeMonoid[A, HKTA, HKTFA any](`
			`fof func(A) HKTA,`
			`fmap func(HKTA, func(A) func(A) A) HKTFA,`
			`fap func(HKTFA, HKTA) HKTA,`

			`m Monoid[A],`
			`) Monoid[HKTA] {`

			`return MakeMonoid(`
			`S.ApplySemigroup(fmap, fap, m).Concat,`
			`fof(m.Empty()),`
			`)`
			`}`